Variators

The invention claimed is: 1. A variator for transmitting rotary motion between a rotary variator input and a rotary variator output at a range of ratios variable between a minimum and a maximum ratio, the variator comprising: an input member operatively coupled to the variator input and an output member operatively coupled to the variator output; transfer means disposed in rolling contact with the input and output members to transfer rotary motion between them; the input member being coupled to the variator input through a first biasing device which is configured to transmit rotary motion from one to the other and is arranged to exert a first biasing force on the variator, the first biasing device having a first, input gain relating input torque acting on the input member to the first biasing force; the output member being coupled to the variator output through a second biasing device which is configured to transmit rotary motion from one to the other and is arranged to exert a second biasing force on the variator, the second biasing device having a second, output gain relating output torque acting on the output member to the second biasing force; the first and second biasing forces both being directed such as to urge the input and output members into engagement with the transfer means to provide traction between them; wherein the first, input gain and second, output gain are different. 2. A variator according to claim 1 , wherein the gain of one of the biasing devices is at least 1% greater than the gain of the other biasing device; optionally wherein the gain of one of the biasing devices is at least 10% greater than the gain of the other biasing device; optionally wherein the gain of one of the biasing devices is at least 25% greater than the gain of the other biasing device. 3. A variator according to claim 1 , wherein the variator is a toroidal variator; optionally wherein the variator is a full-toroidal variator; optionally wherein the variator is a ball bearing or ball-and-disc type variator. 4. A variator according to claim 1 , wherein the variator is configured such that the first and second biasing forces are configured to act in opposition whereby one or other of the first and second biasing forces is configured to dominate and determine a resultant biasing force applied by the first and second biasing devices. 5. A variator according to claim 1 , wherein the first gain is given by a rate of change of the first biasing force with respect to applied input torque and the second gain is given by a rate of change of the second biasing force with respect to applied output torque. 6. A variator according to claim 1 , wherein the first gain when a given torque magnitude is applied to the input is different to the second gain when the same given torque magnitude is applied to the output. 7. A variator according to claim 1 , wherein at least one of the first and second biasing devices comprises a cam and the first and second gain of the first and second biasing device respectively can each be calculated according to the formula: G = T tan ⁡ ( θ ) . R where G is the gain; θ is a local ramp angle of the cam; and R is the distance of the rolling elements from the variator axis. 8. A variator according to claim 1 , wherein at least one of the first and second biasing devices comprises a cam having a ramp, wherein the cam comprises a link configured to transmit torque to one race or to both of the input member and the output member, whereby such torque causes displacement of the cam from a rest position, wherein the link comprises rolling elements that lie on at least one circumferential ramp of the cam. 9. A variator according to claim 8 wherein the at least one ramp has a variable angle that increases with increasing displacement of the cam. 10. A variator according to claim 8 , wherein the ramp includes an endstop to limit the angular rotation of the cam. 11. A variator according to claim 1 , the variator further comprising: an input race and an output race each having a working surface, the races being coaxially mounted for rotation about a variator axis, and a toroidal cavity being defined between the working surfaces; one or more rolling elements disposed between and being in driving engagement with the working surfaces at respective contact regions, each rolling element having at least one contact with a working surface, a second rolling contact, and being mounted on a carriage assembly for rotation about a rolling axis, the contact between the working surface being variable in accordance with a ratio of the variator; wherein: each roller is mounted for pivotal movement that causes a change in a pitch angle of the roller, the pitch angle being about a pitch axis that passes through the contact regions; the variator further comprising a control member operative to actuate the roller to undertake the said pivotal movement thereby changing the pitch angle, so urging the carriage to pivot about its tilt axis and thereby provide a change in variator ratio. 12. A variator according to claim 1 , the variator having a ratio range defined as a ratio between the maximum variator ratio over the minimum variator ratio of greater than 4, greater than 5, greater than 6 or greater than 7. 13. A transmission for a machine or vehicle comprising a variator according to claim 1 , wherein the variator is configured to operate across a variator envelope comprising a magnitude of a total contact power loss of the variator at an absolute maximum speed ratio and a magnitude of a total contact power loss of the variator at an absolute minimum speed ratio, wherein across the entire operating envelope of the variator, the magnitude of the total contact power loss of the variator at the absolute maximum speed ratio is greater than that at the absolute minimum speed ratio and wherein the first, input gain of the input biasing device is greater than that of the second, output biasing device. 14. A transmission for a machine or vehicle comprising a variator according to claim 1 , wherein the variator is configured to operate across a variator envelope comprising a magnitude of a total contact power loss at an absolute maximum speed ratio and a magnitude of a total contact power loss at an absolute minimum speed ratio, wherein across the entire operating envelope of the variator, the magnitude of the total contact power loss of the variator at the absolute maximum speed ratio is less than that at the absolute minimum speed ratio and wherein the second, output gain of the output biasing device is greater than that of the first, input biasing device. 15. A transmission for a machine or vehicle comprising a variator according to claim 1 , wherein the variator is configured to operate across a variator envelope comprising a maximum magnitude of transmitted power at an absolute maximum speed ratio and a maximum magnitude of transmitted power at an absolute minimum speed ratio, wherein across the operating envelope of the variator, the maximum magnitude of transmitted power of the variator at the absolute maximum speed ratio is greater than that at the absolute minimum speed ratio and wherein the gain o